Discrete particle simulations predicting mixing behavior of solid substrate particles in a rotating drum fermenter

A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and...

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Published inBiotechnology and bioengineering Vol. 75; no. 6; pp. 666 - 675
Main Authors Schutyser, M. A. I., Padding, J. T., Weber, F. J., Briels, W. J., Rinzema, A., Boom, R.
Format Journal Article
LanguageEnglish
Published New York John Wiley & Sons, Inc 20.12.2001
Wiley
Subjects
Biological and medical sciences
Bioreactors
Biotechnology
Computer simulation
discrete particle simulations
Entropy
Fermentation
Fundamental and applied biological sciences. Psychology
Image analysis
Methods. Procedures. Technologies
Microbial engineering. Fermentation and microbial culture technology
mixing
scale-up baffles
Sectie Proceskunde
solid-state fermentation
Sub-department of Food and Bioprocess Engineering
Substrates
VLAG
Dimensioning
Solid substrate fermentation
Agitation
Mixing
Solid particle
Simulation
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Abstract A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67% of the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale‐up of mixed solid‐state fermenters. © 2001 John Wiley & Sons, Inc. Biotechnol Bioeng 75: 666–675, 2001.
AbstractList Abstract A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67% of the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale‐up of mixed solid‐state fermenters. © 2001 John Wiley & Sons, Inc. Biotechnol Bioeng 75: 666–675, 2001.
A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67% of the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale‐up of mixed solid‐state fermenters. © 2001 John Wiley & Sons, Inc. Biotechnol Bioeng 75: 666–675, 2001.
A soft-sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid-state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67% of the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale-up of mixed solid-state fermenters.
A soft-sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid-state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67% of the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale-up of mixed solid-state fermenters. copyright 2001 John Wiley & Sons, Inc.
A soft-sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid-state fermentation. In this approach, forces acting on and subsequent motion of individual particles can be predicted. The (2D) simulations were qualitatively and quantitatively validated by mixing experiments using video and image analysis techniques. It was found that the simulations successfully predicted the mixing progress as a function of the degree of filling and size of the drum. It is shown that only relatively large, straight baffles perpendicular to the drum wall (67␘f the drum radius) increase the mixing performance of the rotating drum. Considering the different aspects of mixing dealt with in this work, it is concluded that the soft sphere discrete particle model can serve as a valuable tool for investigating mixing of solid substrate particles. Finally, it is expected that this model may evolve into a potential tool for design and scale-up of mixed solid-state fermenters
Author Schutyser, M. A. I.
Briels, W. J.
Boom, R.
Padding, J. T.
Weber, F. J.
Rinzema, A.
Author_xml – sequence: 1
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  surname: Schutyser
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  email: maarten.schutyser@algemeen.pk.wau.nl
  organization: Wageningen Centre for Food Sciences, PO Box 557, 6700 AN Wageningen, The Netherlands
– sequence: 2
  givenname: J. T.
  surname: Padding
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  organization: University of Twente, Computational Dispersion Rheology, PO Box 217, 7500 AE Enschede, The Netherlands
– sequence: 3
  givenname: F. J.
  surname: Weber
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  organization: Wageningen Centre for Food Sciences, PO Box 557, 6700 AN Wageningen, The Netherlands
– sequence: 4
  givenname: W. J.
  surname: Briels
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  organization: University of Twente, Computational Dispersion Rheology, PO Box 217, 7500 AE Enschede, The Netherlands
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  surname: Boom
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  organization: Wageningen University, Food and Bioprocess Engineering Group, PO Box 8129, 6700 EV Wageningen, The Netherlands; telephone: +31-317-483770; fax: +31-317-482237
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Issue 6
Keywords Dimensioning
Solid substrate fermentation
Agitation
Mixing
Solid particle
Simulation
Language English
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Copyright 2001 John Wiley & Sons, Inc.
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Mitchell DA, Krieger N, Stuart DM, Pandey A. 2000. New developments in solid-state fermentation. II. Rational approaches to the design, operation and scale-up of bioreactors. Proc Biochem 35: 1211-1225.
Allen MP, Tildesly DJ. 1987 Computer simulation of liquids Oxford: Oxford University Press.
1995; 9
2001; 72
2000; 67
1997; 330
1997; 69
1980; 22
1999; 88
1999; 65
1994; 27
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1986
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Allen MP (e_1_2_1_2_1) 1987
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Snippet A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state fermentation....
A soft-sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid-state fermentation....
Abstract A soft‐sphere discrete particle model was used to simulate mixing behavior of solid substrate particles in a slow rotating drum for solid‐state...
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SubjectTerms Biological and medical sciences
Bioreactors
Biotechnology
Computer simulation
discrete particle simulations
Entropy
Fermentation
Fundamental and applied biological sciences. Psychology
Image analysis
Methods. Procedures. Technologies
Microbial engineering. Fermentation and microbial culture technology
mixing
scale-up baffles
Sectie Proceskunde
solid-state fermentation
Sub-department of Food and Bioprocess Engineering
Substrates
VLAG
Title Discrete particle simulations predicting mixing behavior of solid substrate particles in a rotating drum fermenter
URI https://api.istex.fr/ark:/67375/WNG-BVDXWNDR-3/fulltext.pdf
https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fbit.1192
https://www.ncbi.nlm.nih.gov/pubmed/11745144
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https://search.proquest.com/docview/72359373
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Volume 75
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